Multi-scale structural inheritance of fracture systems pattern in coal-bearing measures of the Lorraine-Saar coal Basin

IF 0.6 Q4 GEOCHEMISTRY & GEOPHYSICS
V. Pryvalov, J. Pironon, P. D. Donato, R. Michels, A. Izart, C. Morlot, O. Panova
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Abstract

The Lorraine-Saar Basin (LSB) is one of the major Paleozoic coalfields of Western Europe that has been shapedover two centuries as a heartland of underground coal mining and associated industrial activities in the transborderarea of France and Germany. The Basin still has considerable coal reserves accumulated in numerous laterally continuous coal seams that were affected by processes of thermogenic production of gaseous hydrocarbons during post-Carboniferous burial and related coalification. The LSB stands out by its up to 6 km sedimentary column and its inversion resulting in Paleozoic erosion in the range of 750 m (French part of the Basin) and pre-Mesozoic (Permian) erosion between 1800 and 3000 m (German part of the Basin). Historically, coal production in the Lorraine and the Saar portions of the entire Basin was associated with numerous mining hazards because of the high methane content in coal seams. The LSB has the potential to host an enormous unconventional resource base including coalbed methane (CBM). Coal mines here are no longer operated to produce coal; however, methane generated in deep compartments is venting here via fracture swarms to the Earth’s surface. Cutting natural methane emissions throughout CBM production within coal-bearing terrains is a crucial opportunity for slowing global warming rates. Nearly all CBM plays worldwide are affected in some way by natural multiscale fracture sets ranging from large fault zones to closely spaced joints, micro-shears, or cleat sets in coal seams. The LSB is not excluded indeed from this trend because of the long-term experience of geological exploration during extensive coal mining in the past. Characterization of structural patterns of fracture networks at different scales is a pragmatic process boosting the reliable perception of the performance of coalbed methane gas reservoirs. The focus of this contribution is to get an insight into the style and kinematic description of the multi-scale fault and cleat patterns in the LSB based on results of subsurface and underground geological mapping, and X-ray computer tomography. It will benefit the right mindset to ensure proper technical decisions for efficient exploration and exploitation of CBM reservoirs in the Basin.
洛林—萨尔煤盆地含煤储层断裂体系模式的多尺度构造继承
洛林-萨尔盆地(LSB)是西欧主要的古生代煤田之一,两个多世纪以来一直是法国和德国跨境地区地下煤矿开采和相关工业活动的中心地带。该盆地仍有大量的煤储量,这些煤聚集在许多横向连续煤层中,这些煤层受石炭世后埋藏和相关煤化过程中气态烃的热生成过程的影响。LSB突出的特点是其长达6公里的沉积柱及其反转导致750米范围内的古生代侵蚀(盆地的法国部分)和1800至3000米(盆地的德国部分)之间的前中生代(二叠纪)侵蚀。从历史上看,由于煤层中甲烷含量高,整个盆地的Lorraine和Saar部分的煤炭生产与许多采矿危害有关。LSB拥有巨大的非常规资源基础,包括煤层气(CBM)。这里的煤矿不再生产煤炭;然而,在深层隔间中产生的甲烷通过裂缝群在这里排放到地球表面。在含煤地区的煤层气生产过程中,减少天然甲烷的排放是减缓全球变暖速度的一个关键机会。世界上几乎所有的煤层气区块都在某种程度上受到天然多尺度裂缝集的影响,从大型断裂带到紧密间隔的节理、微剪切或煤层中的清晰集。由于过去在广泛开采煤炭期间的长期地质勘探经验,LSB确实没有被排除在这一趋势之外。在不同尺度上表征裂缝网络的结构模式是一个实用的过程,有助于提高对煤层气气藏动态的可靠认识。本文的重点是基于地下和地下地质填图以及x射线计算机断层扫描的结果,深入了解LSB中多尺度断层的样式和运动学描述,并明确其模式。这将有利于正确的心态,以确保正确的技术决策,从而有效地勘探和开发盆地的煤层气储层。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Geofizicheskiy Zhurnal-Geophysical Journal
Geofizicheskiy Zhurnal-Geophysical Journal GEOCHEMISTRY & GEOPHYSICS-
自引率
60.00%
发文量
50
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